Today (4/25) is national DNA day. Digital World Biology™ is celebrating by sharing some of our favorite structures of DNA. We created these photos with Molecule World™ a new iPad app for viewing molecular structures.

As we are taught in school, the double stranded DNA molecule is a right-handed helix as determined by Watson and Crick using Franklin’s x-ray diffraction images [1]. This B-form of DNA has approximately 10 nucleotides per turn of the helix and is the most common form of DNA found in nature.

Classic structure with the elements colored.

Classic structure with the bases colored.

Classic structure with the strands colored.

However, we’ve heard it said that the first crystal structure of DNA was not right-handed (pers. communication S. Elgin, Washington University). Instead, the high salt and GC base-pairs, used to form the DNA crystals caused the helix to twist in a left-handed way, creating a structure called Z-DNA. Z-DNA occurs in nature, but is most frequently used by marketing departments to [incorrectly] create company logos.

Z-DNA with the elements colored.

Z-DNA with the bases colored.

Z-DNA with the stands colored.

In addition to B- and Z-DNA, DNA can exist in another form known as A-DNA. A-DNA occurs when DNA is dehydrated, but also in DNA/RNA hybrids and double stranded RNA.

A-DNA with the elements colored.

A-DNA with the bases colored.

A-DNA with the strands colored.

Here’s another look at the same molecules, this time head on with the structures rendered in tubes and the bases colored.

Molecule World™ was developed with funding from the National Science Foundation (SBIR IIP 1315426). Any opinions, findings, conclusions, or recommendations expressed on this website are those of the authors and do not necessarily represent the official views, opinions, or policy of the National Science Foundation.

[…] Today (4/25) is national DNA day. Digital World Biology™ is celebrating by sharing some of our favorite structures of DNA. We created these photos with Molecule World™ a new iPad app for viewing molecular structures. […]

The information in this post is very interesting. I have never learnt of any other DNA other than the original structure. It really creates a urge to do further research about the different structures of DNA.

This is all new information since at first year level we have only been taught the basics such as the basic structure , replication models etc. So to most of us , including myself , this is new information which makes it exciting to know how much else there is to learn about . Especially as a student, to be studying genetics and physiology.

They are different three dimensional forms that DNA can assume depending on the environment. Conditions that affect the form are the salt concentration, the sequence, and the amount of water. You can look at the pictures above to see how the forms change.

Perhaps a more accurate description of the right or left handed forming of the helix structure would be describing the way the structure forms due to the polarity of the base-pairs. The DNA helix structure has an anti-parallel configuration, meaning that one strand connects to the other anti-parallel with one strand running from 5′ to 3′ and the other strand running from 3′ to 5′. This also serves as an important base for DNA replication.

After reading this new information I went and did some further research to find the purpose of these different structures and what I found was quite intersting.

The A- structure is actually necassary for the reproduction of B-DNA, the commonly found structure. A conformational switch happens from the B- to underwound A-form starting at the point of nucleotide incorporation and extending to four bases upwards.

And then the Z-structure’s purpose is less infamous. It is found to be used as a basin where the torsional tension in supercoiled DNA collects.

This is indeed an eye opening information which gives explanation to one of the concepts in that have been generalized in Biology as a whole. Such generalisations have led to the limitation of our knowledge and raised misconceptions.

It is of great value that the digital world can help us to resolve such misconceptions.

Does the difference in structure play any significance in the role played by the DNA?

As a first year studying Biochemistry I found this topic interesting, useful and highly informative. I did not know that there were so many types of DNA structures.

This just shows you how little we actually know, and how much studying lies before us. Not to mention al the discoveries that can still be made, as I am sure that scientist do not know absolutely everything yet, they are still researching and studying the structures.

This is the reason I love this field of studying, it is so fascinating and it is always developing and making new discoveries. I will definitely go read up more on these DNA structures and do some research to broaden my knowledge.

What is the major importance in the roles of these structures? How many structures’ existences are we aware of, is it currently only these 3? lastly what in the body exactly triggers them to form these different structures?

“In addition to B- and Z-DNA, DNA can exist in another form known as A-DNA. A-DNA occurs when DNA is dehydrated, but also in DNA/RNA hybrids and double stranded RNA.” Does this only state that a number of DNA strands can have the same composition just different names?

The physical shape is different. The different names are used to describe the different shapes.

Let’s say I have I have two samples of DNA, with the identical sequence. I keep one in water (hydrated) and let the other one dry out (it becomes dehydrated), then I analyze the crystal structure. One would be in the B form, the other would be in the A form.

This blog post gives great insight into the world of DNA. It is informative and aims to broaden the perspectives of people such as myself (a first year BSc Student).

I am definitely inspired by this post because of the interest it ignites in me. I did not realise the complexity in which DNA can exist but after reading this post I appreciate the human body and the essence of its systematic processes.

On comment #23, Just wanted to add that we really appreciate that you like the post. Also, if you want to play with the structures yourself, and have an iPad, you can get the app https://itunes.apple.com/us/app/molecule-world/id863565223?ls=1&mt=8 — The references above include the PDB IDs so you can use Molecule World’s search to get them from MMDB or PDB. Enjoy.

After reading this post I actually went and did some more research on the topic because we are only being taught the basics at the moment. This has definitely sparked a level of interest in the field of genetics

This article leads me to question whether or not other possible forms of DNA could exist and how the change in structure would affect its function as well as its phenotypic expression of the genes? Also what is meant by “but is most frequently used by marketing departments to [incorrectly] create company logos.”?

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